CN103370494A

CN103370494A - System and method for performing downhole stimulation operations

Info

Publication number: CN103370494A
Application number: CN2011800637457A
Authority: CN
Inventors: U·甘古利; 远田仁; X·翁
Original assignee: Prad Research and Development Ltd
Current assignee: Prad Research and Development Ltd
Priority date: 2010-12-30
Filing date: 2011-12-28
Publication date: 2013-10-23
Anticipated expiration: 2031-12-28
Also published as: GB2500332B; GB2500517A; US10563493B2; RU2561114C2; MX2013007565A; WO2012090175A2; CN103282600A; US20120185225A1; GB2500332A; WO2012090175A3; GB2500517B; GB201310333D0; US20160115771A1; CA2823115A1; CN103282600B; RU2013135493A; GB201310311D0; WO2012090174A2; US9228425B2; AU2011350664B2

Abstract

A system and method for performing stimulation operations at a wellsite having a subterranean formation with of a reservoir therein is provided. The method involves performing reservoir characterization to generate a mechanical earth model based on integrated petrophysical, geomechanical and geophysical data. The method also involves generating a stimulation plan by performing well planning, a staging design, a stimulation design and a production prediction based on the mechanical earth model. The stimulation design is optimized by repeating the well planning, staging design, stimulation design, and production prediction in a feedback loop until an optimized stimulation plan is generated.

Description

Be used for carrying out the system and method for down-hole stimulation work

The fork that related application is handed over is quoted

The application requires the U.S. Provisional Application No.61/464 of submission on February 28th, 2011, the U.S. Provisional Application No.61/460 that on December 30th, 134 and 2010 submitted to, 372 priority, both all are entitled as " integrated reservoir (reservoir) center completion and volume increase (stimulation) method for designing (INTEGRATED RESERVOIR CENTRIC COMPLETION AND STIMULATION DESIGN METHODS) "; Full content with above-mentioned each U.S. Provisional Application is herein incorporated by reference.

Background technology

The disclosure relates to for the technology of carrying out oil field operation.More specifically, the disclosure relates to for carrying out stimulation work, such as the subterranean strata that wherein has at least one reservoir is carried out perforation (perforating), injection and/or pressure break.The statement of this part only provides the background technical information relevant with the disclosure, and does not consist of prior art.

Can carry out oil field operation so that valuable down-hole (downhole) fluid such as hydrocarbon is positioned and gathers.Oil field operation can comprise for example exploration, drilling well, down-hole assessment, completion, exploitation, volume increase and oil field analysis.Exploration can relate to the seismic prospecting that example such as seismopickup come the sending and receiving underground signal.Drilling well can relate to downhole tool is advanced in the soil to form well.The down-hole is assessed to relate to downhole tool is deployed in the well to carry out underground survey and/or to fetch the down-hole sample.Completion can relate to cements the well and sleeve pipe to well, exploits with preparation.Exploitation can relate to production tubing is deployed in the well, so that fluid is transferred to ground (surface) from reservoir.Volume increase can relate to for example perforation, pressure break, injection and/or other stimulation work, so that from the reservoir production fluid.

The oil field is analyzed can relate to the information of for example assessing relevant well site (wellsite) and various operations, and/or carries out well planning operation.Such information can be the petrology information that for example gathered by the petrologist and/or analyze, the geology information that is gathered and/or analyzed by the geologist or the geophysics's information that is gathered and/or analyzed by the Geophysicist.Analyzed respectively in the situation that petrology information, geology information, geophysics's information can the data flow between them disconnect.Operating personnel can manually move and analyze data with various software and instrument.Can use well planning, the information about the well site based on gathering designs oil field operation.

Summary of the invention

It partly is in order to introduce the following concept through selecting that will further describe in detailed description that this summary of the invention is provided.This summary of the invention partly is not intended to determine key or the essential feature of theme required for protection, also is not intended to the scope of helping limit theme required for protection.

Relevant with the stimulation work that relates to the reservoir characterization of using mechanics earth model and comprehensive well site data (for example, petrology, geology, geomechanics and geophysical data) in this disclosed technology.Described stimulation work can also relate to well planning grading design, volume increase design and the production forecast of optimizing in feedback loop.Can optimize described volume increase planning by in feedback loop, carrying out described volume increase design and production forecast.Can also plan to carry out described optimization with the classification in the described feedback loop and well.Can carry out described volume increase planning, and the described volume increase planning of real-time optimization.Described volume increase design can be based on the classification for unconventional reservoir, unconventional reservoir all in this way tight gas layer of sand and shale reservoir.

Description of drawings

Embodiment for the method and system of carrying out the down-hole stimulation work is described with reference to the drawings.For uniformity, element like the identical Reference numeral intention representation class.For purpose clearly, in each accompanying drawing, each parts is marked.

Fig. 1 .1-1.4 is the schematic diagram of the various oil field operations at place, diagram well site.

Fig. 2 .1-2.4 is the schematic diagram by the data of the operation collection of Fig. 1 .1-1.4.

Fig. 3 .1 is the schematic diagram in the well site of the various down-holes of diagram stimulation work.

Fig. 3 .2-3.4 is the schematic diagram in various cracks in the well site of Fig. 3 .1.

Fig. 4 .1 is the schematic flow diagram of diagram down-hole stimulation work.

Fig. 4 .2 and 4.3 is schematic diagrames of the part of diagram down-hole stimulation work.

Fig. 5 .1 is illustrated in the schematic diagram that in the tight gas sandstone formation (tight gas sandstone formation) stimulation work is carried out the method for classification, and Fig. 5 .2 is illustrated in the flow chart that in the tight gas sandstone formation stimulation work is carried out the method for classification.

Fig. 6 is the schematic diagram that diagram is combined to form one group of log of the compound log of weighting (log).

Fig. 7 is that diagram is according to the schematic diagram of the reservoir quality index (indicator) of the first and second logs formation.

Fig. 8 is that diagram is according to the schematic diagram of the composite quality index of completion and the formation of reservoir quality index.

Fig. 9 is that diagram is based on the schematic diagram of level (stage) design of stress distribution and composite quality index.

Figure 10 is the schematic diagram that diagram is used for the conforming level boundary adjustment of raising composite quality index.

Figure 11 is that diagram is based on the schematic diagram of the level of composite quality index decomposition.

Figure 12 is the figure that diagram is arranged based on the perforation of quality index.

Figure 13 is the method for classification is carried out in diagram to the stimulation work of shale reservoir flow chart.

Figure 14 is the flow chart that the method for down-hole stimulation work is carried out in diagram.

The specific embodiment

Following description comprises example system, device, method and the command sequence of the technology of implementation the theme here.Yet should be appreciated that can be in the situation that there be these details to implement described embodiment.

The disclosure relates to design, realization and the feedback of the stimulation work of carrying out in the well site.Can carry out stimulation work with reservoir center, integration scenario.These stimulation work can relate to based on Reservoir data from multiple disciplines (for example being used by petrologist, geologist, geomechanics man, Geophysicist and reservoir engineer), many wells use and/or the comprehensive volume increase design of multistage oil field operation (for example completion, volume increase and exploitation).Some application can be adjusted to be applicable to unconventional well site and use (such as tight gas, shale, carbonate, coal etc.), complicated well site and use (for example many wells) and various fractured model (for example, for the conventional plane double-vane fractured model of sandstone reservoir or for the complex network fractured model of the low-permeability reservoir of dry) etc.As used herein, unconventional reservoir relates to the reservoir such as tight gas (tight gas), layer of sand, shale, carbonate, coal etc., and wherein the stratum is inhomogeneous, is perhaps run through (all other reservoirs are regarded as conventional reservoir) by dry.

Also can use optimization, the adjustment of the reservoir (such as tight gas, shale, carbonate, coal etc.) for particular type, Comprehensive Evaluation Standard (for example reservoir and completion standard), and comprehensively from the data in a plurality of sources, carry out stimulation work.Can analyze respectively data flow with routine techniques and manually carry out stimulation work, wherein analysis is disconnected respectively, and/or relates to operating personnel's usefulness various software and the next manual Mobile data of instrument and integrated data.Also comprehensive these stimulation work are for example by making multidisciplinary data maximize these stimulation work of streaming in automatic or semi-automatic mode.

Oil field operation

Fig. 1 .1-1.4 illustrates the various oil field operations that can carry out in the well site, and Fig. 2 .1-2.4 illustrates the various information that can collect in the well site.Fig. 1 .1-1.4 illustrates the rough schematic view in representative oil field or well site 100, and this representativeness oil field or well site 100 have subsurface formations 102, comprises for example reservoir 104 in the subsurface formations 102, and illustrates the various oil field operations that well site 100 is carried out.Fig. 1 .1 illustrates the exploration operation by the attribute of carrying out to measure subsurface formations such as the exploration instrument of seismopickup 106.1.Exploration operation can be the seismic exploration for generation of acoustic vibration.In Fig. 1 .1, a plurality of leveling courses 114 places of a kind of such acoustic vibration 112 in earth formation 116 that generated by source 110 reflect.Can receive acoustic vibration 112 by the sensor such as geophone-receiver 118 that is positioned at earth surface, and geophone 118 generation electrical output signals, the data 120 that receive in Fig. 1 .1, be called.

In response to the acoustic vibration that receives 112 of the different parameters that represents acoustic vibration 112 (such as amplitude and/or frequency), geophone 118 can produce the electrical output signal of the data that comprise relevant subsurface formations.Can provide the data 120 that receive as the input data to the computer 122.1 of seismopickup 106.1, and in response to the input data, computer 122.1 can generate earthquake and microseism data output 124.Can export 124 to geological data stores, sends or carry out further processing such as data reduction according to expectation.

Fig. 1 .2 illustrates the drillng operation of being carried out by drilling tool 106.2, and wherein drilling tool 106.2 is hung by rig 128, and is advanced in the subsurface formations 102, to form well 136 or other passage.Can use mud sump 130 that drilling mud is drawn in the drilling tool via pipeline 132, so that drilling mud cycles through drilling tool, upward to well 136 and return ground.Drilling mud can be filtered, and then returns mud sump.Can store with the circulating system, the drilling mud of control or filter flowing.In this diagram, drilling tool is advanced to subsurface formations to arrive reservoir 104.Each well can be take one or more reservoirs as target.Drilling tool can be suitable for coming attribute under the measuring well with the well logging during instrument.The well logging during instrument can also be suitable for collecting as shown rock core sample 133, perhaps is removed in order to can collect the rock core sample with other instrument.

Can communicate with surface units 134 and drilling tool and/or operation outside the venue.Surface units can be communicated by letter with drilling tool, orders to send to drilling tool, and from the drilling tool receive data.Surface units can have computer equipment, to receive, store, to process and/or to analyze the data from operation.Surface units can be collected the data that generate during the drillng operation, and produces the data output 135 that can be stored or send.Computer equipment, for example the computer equipment in the surface units can be positioned near various positions, well site and/or be positioned at off-site location.

Can near the oil field, settle the sensor (S) such as batchmeter, to collect the data relevant with previously described various operations.As shown, sensor (S) can be placed in the drilling tool one or more positions and/or be positioned at the rig place, to measure drilling parameter, such as the pressure of the drill, torque-on-bit, pressure, temperature, flow, composition, rotary speed and/or other job parameter.Sensor (S) can also be arranged in one or more positions of the circulating system.

Can collect the data that gathered by sensor by surface units and/or other Data Collection source, to analyze or other processing.Can use separately or be combined with other data the data of being collected by sensor.Data Collection can be carried out in the field or sends outside the venue in one or more databases and/or to it.Optionally the part whole or that select of usage data is come current and/or other well are analyzed and/or predicted operation.Data can be historical data, real time data or its combination.Can be used in real time real time data, or its storage is used in order to later.Can also be with data and historical data or other input combination further to analyze.Can store data in minute other database, perhaps be combined in the individual data storehouse.

Can come execution analysis with collected data, such as modelling operability.For example, can export to carry out geology, geophysics and/or reservoir engineering analysis with geological data.Can carry out reservoir, well, geology and geophysics or other simulation with the data after reservoir, well, ground and/or the processing.Data output from operation can directly generate from sensor, or generates after some preliminary treatment or modeling.These data outputs can be as the input of other analysis.

Data can be collected and be stored in surface units 134 places.One or more surface units can be positioned at the place, well site or be connected to a long way off the well site.Surface units can be the complex network of individual unit or a plurality of unit, is used for carrying out the data management function of whole oil field necessity.Surface units can be system manually or automatically.Surface units 134 can and/or be adjusted by user's operation.

Surface units can have transceiver 137, so that can communicate between the various piece of surface units and current oil well or other position.Surface units 134 can also have or functionally be connected to one or more controllers, is used for activating the mechanical device at 100 places, well site.Then surface units 134 can send command signal to the oil field in response to the data that receive.Surface units 134 can receive order via transceiver, perhaps can oneself carry out the order to controller.Can provide processor to analyze data (Local or Remote), make decision and/or the actuation control device.By this way, can adjust operation based on collected data selection ground.Can optimize Partial Jobs based on this information, such as control drilling well, the pressure of the drill, pump rate or other parameter.These adjustment can be carried out automatically based on computer protocol, and/or are manually carried out by the operator.In some cases, can adjust well and plan to select best operating condition, perhaps avoid problem.

Fig. 1 .3 illustrates by rig 128 and hangs and enter the wireline logging operation that wireline logging (wireline) instrument 106.3 of the well 136 of Fig. 1 .2 is carried out.Wireline logging instrument 106.3 can be suitable for being deployed in the well 136, is used for producing log, carries out downhole testing and/or collects sample.Wireline logging instrument 106.3 can be used to provide the another kind of method and apparatus of carrying out seismic exploration.The wireline logging instrument 106.3 of Fig. 1 .3 can for example have explosivity, radioactivity, electricity or acoustic energy source 144, and these energy source 144 peripherad subsurface formations 102 and fluid wherein send the signal of telecommunication and/or receive the signal of telecommunication from subsurface formations on every side 102 and fluid wherein.

Wireline logging instrument 106.3 can be operatively attached to for example geophone 118 and the computer 122.1 of the seismopickup 106.1 of Fig. 1 .1.Wireline logging instrument 106.3 earthward unit 134 provides data.Surface units 134 can be collected in the data that generate between the wireline logging operational period, and produces the data output 135 that can be stored or send.Wireline logging instrument 106.3 can be arranged in the various degree of depth of well, so that exploration result or the out of Memory relevant with subsurface formations to be provided.

Can near well site 100, settle the sensor (S) such as batchmeter, to collect the data relevant with previously described various operations.As shown, sensor (S) is placed in the wireline logging instrument 106.3, relates to for example parameter of other parameter of porosity, permeability, fluid composition and/or operation with measurement.

Fig. 1 .4 illustrates the mining operations of being carried out by the exploitation instrument 106.4 the well of finishing 136 of disposing and entering Fig. 1 .3 from production unit or Christmas tree 129, is used for fluid is drawn into ground installation 142 from downhole in reservoir.Fluid flows through the perforation the sleeve pipe (not shown) and enters exploitation instrument 106.4 in the well 136 from reservoir 104, and flows to ground installation 142 via collection network 146.

Can near the oil field, settle the sensor (S) such as batchmeter, to collect and previously described various operation relevant datas.As shown, sensor (S) can be placed in exploitation instrument 106.4 or the relevant device, in Christmas tree 129, collection network, ground installation and/or production facility, to measure fluid parameter, such as other parameter of fluid composition, flow, pressure, temperature and/or mining operations.

Although only show the well site configuration of simplification, be to be understood that oil field or well site 100 can cover the part in land, ocean and/or waters with one or more well sites.In order to increase recovery ratio or to store for example hydrocarbon, carbon dioxide or water, exploitation also can comprise the Injection Well (not shown).One or more collecting devices can be operatively attached to one or more well sites, optionally to collect downhole fluid from the well site.

Should be appreciated that the illustrated instrument of Fig. 1 .2-1.4 not only can measure the oil field attribute but also can measure the attribute of non-oil field operation, such as mineral reserve, aquifer, storage and other underground installation.And, although illustrate specific data acquisition tools, but should be appreciated that can use can sensing such as subsurface formations earthquake two-way travel time, density, resistivity, coefficient of mining etc. and/or the various survey tools (such as wireline logging, measurement while drilling (MWD), well logging during (LWD), rock core sample etc.) of the parameter of its geology information.Can various sensors (S) be set in various positions along well and/or monitoring tool, to collect and/or to monitor desired data.Can also provide other data source from position outside the venue.

Well site 100 and the example by the operable various operations of technology that provide here are provided the configuration of the oil field of Fig. 1 .1-1.4.The oil field partly or entirely can be on land, waterborne and/or marine.Although illustrate the situation of measuring single oil field in single position, can utilize the reservoir engineering with any combination in one or more oil fields, one or more treatment facility and one or more well sites.

Fig. 2 .1-2.4 is respectively the diagrammatic representation by the example of the data of the instrument collection of Fig. 1 .1-1.4.Fig. 2 .1 represents the seismic channel 202 of the subsurface formations of Fig. 1 .1 of being obtained by seismopickup 106.1.Seismic channel can be used for providing such as the data in the two-way response of a period of time.Fig. 2 .2 illustrates the rock core sample 133 of being collected by drilling tool 106.2.The rock core sample can be used for providing such as the data along the chart of density, porosity, permeability or other physical attribute of the rock core sample of the length of rock core.Can under the pressure and temperature that changes, carry out the test of density and viscosity to the fluid in the rock core.Fig. 2 .3 illustrates the log 204 of the subsurface formations of Fig. 1 .3 that is obtained by wireline logging instrument 106.3.Wireline logging can provide resistivity or other measurement result on various depths stratum.Fig. 2 .4 illustrates production rate decline curve or the chart 206 of the fluid of the subsurface formations that flows through Fig. 1 .4 of measuring at ground installation 142 places.Production rate decline curve can be provided as the coefficient of mining Q of the function of time t.

Fig. 2 .1,2.3 illustrates the example of static measurement of information of the physical characteristic of the reservoir that can describe or provide relevant stratum and wherein comprise with each chart of 2.4.Can analyze these measurement results to limit the attribute on stratum, determine the accuracy of measurement result and/or check mistake.The figure of each in each measurement result can be alignd (align) and convergent-divergent (scale), with the comparison of carrying out attribute with examine.

Fig. 2 .4 illustrates the example by the kinetic measurement of well convection cell attribute.Along with flow is crossed well, the convection cell attribute grades such as flow, pressure, one-tenth, measures.As described below, can analyze the Static and dynamic measurement result, and generate the model of subsurface formations with them, to determine its characteristic.Also can measure the aspect, stratum over time with similar measurement.

Stimulation work

Fig. 3 .1 illustrates the stimulation work that 300.1 and 300.2 places carry out in the well site.Well site 300.1 comprises rig 308.1, and rig 308.1 has the vertical well 336.1 that extends into stratum 302.1.Well site 300.2 comprises rig 308.2 and rig 308.3, and rig 308.2 has well 336.2, and rig 308.3 has well 336.3, and well 336.3 extends into respectively subterranean strata 302.2 below rig 308.3.Although show the customized configuration that well site 300.1 and 300.2 has rig and well, should be appreciated that one or more rigs and one or more well can be placed in place, one or more well site.

Well 336.1 extends through unconventional reservoir 304.1-304.3 from rig 308.1.Well 336.2 and 336.3 extends to unconventional reservoir 304.4 from rig 308.2 and 308.3 respectively.As shown, unconventional reservoir 304.1-304.3 is tight gas layer of sand reservoir, and unconventional reservoir 304.4 is shale reservoirs.Can there be one or more unconventional reservoirs (such as tight gas, shale, carbonate, coal, heavy oil etc.) and/or conventional reservoir in the given stratum.

The stimulation work of Fig. 3 .1 can be carried out separately or carry out in conjunction with other oil field operation such as the oil field operation of Fig. 1 .1 and 1.4.For example, can as shown in Fig. 1 .1-1.4, come to well 336.1-336.3 measure, drilling well, test and exploitation.The stimulation work that well 300.1 and 300.2 places carry out can relate to such as perforation, pressure break, injection etc.Stimulation work can be carried out in conjunction with other oil field operation (referring to for example Fig. 1 .4) such as completion and mining operations.Shown in Fig. 3 .1, well 336.1 and 336.2 is by completion, and has perforation 338.1-338.5 so that exploitation.

Contiguous tight gas layer of sand reservoir 304.1 is settled downhole tools 306.1 in vertical well 336.1, to carry out underground survey.In well 336.1, settle packer 307, to isolate the part of its contiguous perforation 338.2.In case near well, form perforation, just can inject fluid to the stratum by perforation, to create and/or expansion crack wherein, to promote the exploitation from reservoir.

The reservoir 304.4 on stratum 302.2 carried out perforation, and settled packer 307 with near isolation well 336.2 perforation 338.3-338.5.As shown, in horizontal hole 336.2, at the level St of well ₁And St ₂The place has settled packer 307.As also illustrated, well 304.3 can be to extend through the offset well (test well) that stratum 302.2 arrives reservoir 304.4.One or more wells can be positioned at place, one or more well site.Can a plurality of wells be set by expectation.

The crack can extend into various reservoir 304.1-304.4, so that production fluid therefrom.Near well 304, schematically show the example in the crack that can form among Fig. 3 .2 and 3.4.Shown in Fig. 3 .2, dry 340 is extended near well 304 in layer.Near well 304, can form perforation (or perforation bunch) 342, can inject fluids 344 and/or be mixed with the fluid of proppant 346 by perforation 342.Shown in Fig. 3 .3, can be by injecting through perforation 342, along maximum stress face σ _HmaxCreate the crack, and open and expand dry and carry out fracturing.

Fig. 3 .4 shows near another view of the fracturing work the well 304.In this view, inject crack 348 and near well 304, radially extend.Can arrive near the well 304 microseismic event bag (pocket of seismic event) 351 (schematically being shown a little) with the injection crack.Can use fracturing work as the part of stimulation work, be convenient to hydrocarbon and move to the path of well 304 to exploit in order to provide.

Return with reference to figure 3.1, can near oil well, settle the sensor (S) such as batchmeter, to collect the data relevant with previously described various operations.During pressure break, can near the stratum, settle some sensors such as geophone, be used for measuring the microseism ripple, and carry out microseism mapping (mapping).Can collect the data that gathered by sensor by surface units 334 and/or other Data Collection source, to carry out previous described analysis or other processing (referring to for example surface units 134).As shown, surface units 334 is linked to network 352 and other computer 354.

Can provide volume increase instrument 350 as the part of surface units 334 or the other parts in well site, be used for carrying out stimulation work.For example, can being used for the well planning of one or more wells, one or more well site and/or one or more reservoirs, use the information that during one or more stimulation work, generates.Volume increase instrument 350 can operationally be linked to one or more rigs and/or well site, and is used for receive data, deal with data, transmits control signal etc., and this will further describe hereinafter.Volume increase instrument 350 can comprise: reservoir characterization unit 363 is used for generating mechanics earth model (MEM); Volume increase planning unit 365 is used for generating volume increase planning; Optimizer 367 is used for optimizing volume increase planning; Unit 369 is used for real-time optimization is carried out in the volume increase planning of optimizing in real time; Control module 368 is optionally adjusted stimulation work for planning based on the volume increase of real-time optimization; Renovator 370 is used for upgrading the reservoir characterization model based on volume increase planning and the later stage assessment data of real-time optimization; And prover 372, for the volume increase planning of as hereinafter will further describing, calibrating optimization.Volume increase planning unit 365 can comprise: grading design instrument 381 is used for carrying out grading design; Volume increase design tool 383 is used for carrying out the volume increase design; Production forecast instrument (production prediction tool) 385 is used for forecast production; And well Planning Tool 387, plan for generation of well.

To 3D seismic data (referring to for example Fig. 2 .1-2.4), the scope of the well site data of using in the stimulation work can be for explaining to petrology from for example rock core sample based on log.Volume increase design for example can utilize that rock technical expert in oil field carries out manual handle, to collate many different information.Whether the manual operation of the workflow (workflow) that comprehensively can relate to disconnection of information and output is such as the identification in the completion district of delineating, expecting of reservoir region, to the estimation of the fracturing growth of given completion equipment configuration expectation, reach and arrange that wherein another well or a plurality of well are with decision that the stratum is increased production better etc.This volume increase design can also relate to semi-automatic or automatic Synthesis, feedback and control, so that stimulation work.

Can be based on the stimulation work of the understanding of reservoir being carried out to conventional or unconventional reservoir.For example be used for design (for example spacing and orientation) and the geomechanics model of perforation and the optimum target district of classification, a plurality of wells in well planning, identification, can use reservoir characterization.Can come the volume increase design is optimized based on resulting production forecast.These volume increase designs can relate to integrated reservoir central task flow process, and it comprises design, real-time (RT) and processes rear evaluation means (component).Can when using multidisciplinary well and reservoir data, carry out completion and volume increase design.

Fig. 4 .1 is the schematic flow diagram 400 of the stimulation work of the stimulation work of diagram shown in Fig. 3 .1.Flow chart 400 is with integrated information and analyzes the iterative process that designs, implements and upgrade stimulation work.The method relates to preliminary treatment and assesses 445, increases production planning 447, processes in real time optimization 451 and/or design/model modification 453.Flow chart 400 partly or entirely can iteration, in existing or additional well, to adjust stimulation work and/or the additional stimulation work of design.

Pre-volume increase assessment 445 relates to reservoir characterization 460 and generating three-dimensional mechanics earth model (MEM) 462.Can pass through integrated information, such as the information that in Fig. 1 .1-1.4, gathers, generate reservoir characterization 460, carry out modeling so that use from the unified combination of the information of historical independent technique standard or subject (for example petrologist, geologist, geomechanics man and Geophysicist, and previous crack treatment result).Can generate such reservoir characterization 460 with the Integrated Static modeling technique, generating MEM462, described at U.S. Patent application No.2009/0187391 and 2011/0660572 for example.As example, can use such as from SCHLUMBERGER ^TMCommercial available such as PETREL ^TM, VISAGE ^TM, TECHLOG ^TM, and GEOFRAME ^TMSoftware carry out preliminary treatment assessment 445.

Reservoir characterization 460 can relate to the various information of catching such as the data related with subsurface formations, and develops one or more reservoir models.The information of catching can comprise for example increases production information, distributes such as reservoir (produce oil) district, geomechanics (stress) district, dry.Can carry out reservoir characterization 460 so that in pre-volume increase assessment, comprise the information of relevant stimulation work.Generate MEM462 and can simulate the subterranean strata (for example generating the stress state of given stratigraphic section in oil field or the basin and the numeric representation of rock mechanics attribute) of developing.

Can generate MEM462 with conventional geology mechanical modeling.The example of MEM technology is provided among the U.S. Patent application No.2009/0187391.The information of oil field operation collection that can be by example such as Fig. 1 .1-1.4,2.1-2.4 and 3 generates MEM462.For example, 3D MEM can consider the various reservoir data of collecting in advance, is included in the geological data collected between the early stage exploratory period to the stratum and the log data (referring to for example Fig. 1 .1-1.4) by the drilling well of one or more exploratory wells is collected before exploitation.MEM462 can be used for providing the geomechanics information that for example is used for various oil field operations, selects, the optimization of casing string quantity, gets out stable well, design completion, carries out fracturing yield increasing etc. such as casing setting depth.

The MEM462 that generates can be as the input of carrying out volume increase planning 447.Can make up 3DMEM to identify potential drilling well site.In one embodiment, when the stratum basically even, and when there is no large dry and/or heavily stressed barrier, can suppose that in the preset time section fracturing fluid with the specified rate of given speed pumping will generate substantially the same fracture network in the stratum.Useful Information when the rock core sample shown in Fig. 1 .2 and 2.2 can be provided in the crack attribute of analyzing the stratum.For the zone that presents like attribute in the reservoir, can arrange a plurality of wells (or branch) with the distance that is substantially equal to one another, and will fully increase production whole stratum.

Volume increase planning 447 can relate to well planning 465, grading design 466, volume increase design 468 and production forecast 470.Particularly, MEM462 can be the input to well planning 465 and/or grading design 466 and volume increase design 468.Some embodiment can comprise semi-automatic method, to identify for example well spacing and orientation, multi-stage perforator design and Hydraulic Fracturing Design.In order to process a large amount of different characteristics in the hydrocarbon reservoir, some embodiment can relate to the special method for the target reservoir environment, the target reservoir environment is in this way all, but is not limited to, tight gas stratum, sandstone reservoir, dry shale reservoir or other unconventional reservoir.

Volume increase planning 447 can relate to the interval (interval) that disperses for by subsurface formations being divided into many groups, based on such as geophysics's attribute on stratum and with the information of the vicinity of dry each interval being characterized, then a plurality of intervals are grouped into one or more drilling well sites again, each well site holds the branch of well or well, identifies the method for the semi-automation of potential drilling well site.Can when optimize the exploitation of reservoir, determine and use spacing and the orientation of a plurality of wells.The characteristic that can analyze each well is used for level planning and volume increase planning.In some cases, can provide the completion consultant (advisor), for example be used for after the refinement workflow of recurrence, analyzing the tight gas sandstone reservoir vertically or vertical well almost.

Can before such oil field operation is carried out in the well site, carry out well planning 465 with the design oil field operation.Can plan that 465 limit equipment and the job parameter that for example is used for carrying out oil field operation with well.Some such job parameters can comprise for example perforation position, operational pressure, stimulation fluid and employed other parameter in volume increase.When planned well is planned, can use the information that gathers from each provenance, all in this way historical datas of the information of collection, given data, oil field measurement result (for example obtained in Fig. 1 .1-1.4).In some cases, can analyze the data of when forming well planning, using with modeling.The well that generates in volume increase planning is planned the input that can receive from grading design 466, volume increase design 468 and production forecast (production prediction) 470, so that assessment is about the information of volume increase and/or impact volume increase in well planning.

Can also use well planning 465 and/or MEM462 as the input to grading design 466.In grading design 466, can use reservoir and other data, to be defined for the operations specific parameter of volume increase.For example, grading design 466 can relate to limited boundary in well, to carry out the stimulation work that further describes here.The example of grading design has been described among the U.S. Patent application No.2011/0247824.Grading design can be for the input of carrying out volume increase design 468.

Increased production design limiting for the various volume increase parameters (for example perforation layout) of carrying out stimulation work.Can carry out for example crack modeling with volume increase design 468.U.S. Patent application No.2008/0183451,2006/0015310 and the open No.WO2011/077227 of PCT in the example of crack modeling has been described.The volume increase design can relate to the volume increase part that limits volume increase planning and/or well planning with various models.

Comprehensively 3D reservoir model (stratigraphic model) is as the starting point (section model) of well completion design in the volume increase design, and this 3D reservoir model can be the result of seismic interpretation, geosteering while drilling explanation, geology or geomechanics earth model.For some volume increase designs, can read 3D MEM with the crack modeling algorithm, and operation is just being drilled modeling and is being predicted crack growth.Can come so that can in stimulation work, consider the special heterogeneity of complicated reservoirs with this process.In addition, certain methods can be incorporated the space X of data-Y-Z set into, to derive index, then arranges and/or carries out wellbore operations with this index, and in some cases, arrange and/or carry out multistage wellbore operations, as further describing here.

The volume increase design can be used the 3D reservoir model, for the information of the relevant dry that supplies a model.Can for example process with dry information the situation of some, the crack growth of inducing such as waterpower and the situation that runs into dry (referring to for example Fig. 3 .2-3.4).In this case, the crack can continued growth enter identical direction, and turns to or stop along the dry face according to angle of incidence and other reservoir geology mechanical attribute.These data can provide the existence of natural stress and knowing clearly of distribution in the minimum and maximum stress level of each position in for example reservoir size and structure, position, oil-producing area and border, the stratum and the stratum.As the result of this simulation, can form nonplanar (i.e. networking) crack or discrete network crack.The a few thing flow process can be in the single 3D painting canvas that has stacked microseismic event (referring to for example Fig. 3 .4) fractured model of comprehensive these predictions.This information can be used for fracture design and/or calibration.

In the volume increase design, also can shine upon to understand the complex fracture growth with microseism.The complex fracture growth may appear in the unconventional reservoir such as the shale reservoir.Essence and the degree that can analyze the crack complexity design and the completion strategy to select the best to increase production.Can predict the crack geometry that can be calibrated and come optimum design based on real-time microseism mapping and assessment with the crack modeling.Can make an explanation based on the growth of existing hydraulic fracture Model on Crack seam.For unconventional reservoir (for example tight gas layer of sand and shale), also can carry out some complicated hydraulic fractures and propagate modeling and/or explanation, will further describe here.Can assess to proofread and correct reservoir attribute and initial modeling assumption based on microseism, and optimize fracture design.

The example of complex fracture modeling is provided in SPE paper 140185, by reference its full content has been herein incorporated.Two kinds of application that the complex fracture modeling technique shines upon in conjunction with microseism have been illustrated in this complex fracture modeling, with sign crack complexity, and assessment completion performance.The first complex fracture modeling technique is analytical model, for assessment of the distance between crack complexity and the orthogonal fracture.The assessment that the second utilization grid number value model, this grid number value model allow the complicated geological description and complex fracture is propagated.These examples have been illustrated and can how to be utilized embodiment to assess the impact how the crack complexity is subjected to the change of the design of crack treatment in each geological environment.In order to use the complex fracture model, and no matter the inherent uncertainty in MEM and " reality " crack growth, quantize the impact of the change of fracture design, comprehensively microseism mapping and complex fracture modeling are to explain the microseism measurement result, and also calibration complexity is increased production model simultaneously.Such example illustrates the crack complexity and can change with the geology condition.

Production forecast 470 can relate to based on well planning 465, grading design 466 and increase production design 468 and come estimated output.After can waiting until, the result of volume increase design 468 (being simulation fracture model and input reservoir model) uses, be used for the production forecast workflow, wherein conventional analysis or numerical value reservoir simulation device can operate this model, and come predict carbon hydrogen compound output based on dynamic data.Pre-production forecast 470 can be useful for for example quantitative verification volume increase planning 447 processes.

Indicated such as flow arrow, can iteration carry out the part or all of of volume increase planning 447.As shown, after grading design 466, volume increase design 468 and production forecast 470, can provide optimization, and optimize to be used as and feed back, to optimize 472 wells planning 465, grading design 466 and/or volume increase design 468.Can optionally carry out optimization, with the part or all of result of feedback from volume increase planning 447, and iterate to as required the various piece of increasing production planning process, and reach the result of optimization.Can manually carry out volume increase planning 447, perhaps process with Automatic Optimal and comprehensively increase production planning 447, schematically illustrated such as the optimization 472 in the feedback loop 473.

Fig. 4 .2 schematically illustrates the part of volume increase planning operation 447.As shown in this figure, grading design 446, volume increase design 468 and production forecast 470 can be in feedback loop 473 iteration, and optimised 472 to generate the results 480 that optimize, such as the volume increase planning of optimizing.This alternative manner is so that input and the results that generated by grading design 466 and volume increase design 468 can ' mutually study ', and and the production forecast iteration to carry out the optimization between them.

Can design and/or optimize the various piece of stimulation work.The example of Optimum Fracturing has been described in U.S. Patent No. 6508307 for example.In another example, can also in volume increase planning 447, provide the finance input such as the pressure break cost that can affect operation.Can by when considering the finance input, designing for the output optimization level, carry out optimization.Such finance input can relate to the cost such as the various stimulation work in each grade place in the illustrated well among Fig. 4 .3.

Fig. 4 .3 illustrates the graded operation that carries out at each interval place and relevant net present value (NPV) (net present value) associated with it.Shown in Fig. 4 .3, consider net present value (NPV) Figure 45 7, can consider various grading design 455.1 and 455.2.Net present value (NPV) Figure 45 7 is charts of drawing the relation of average after-tax net present value (NPV) (y axle) and net present value (NPV) standard deviation (x axle).Can be based on various grading design are selected in the financial analysis of net present value (NPV) Figure 45 7.For example having described the technology that is used for optimizing fracture design that relates to such as the financial information of net present value (NPV) in the U.S. Patent No. 7908230, by reference its full content is herein incorporated.In this is analyzed, can carry out various technology, such as Monte Carlo simulation.

Return with reference to figure 4.1, in volume increase planning 447, can comprise various optional features.For example, can determine whether in the stratum, to make up a plurality of wells with many well planning consultants.If form a plurality of wells, many well planning consultants can provide spacing and the orientation of a plurality of wells, and the optimum position of the stratum being carried out perforation and processing in each well.As used herein, term " many wells " can refer to get into from earth surface independently respectively a plurality of wells of subterranean strata; Term " many wells " also can refer to from a plurality of branches (referring to for example Fig. 3 .1) of the single well initial (kick off) that gets out from earth surface.The direction of well and branch can be vertical, level or vertically and any direction between the level.

When planning or boring a plurality of well, can repeat simulation to each well, so that each well has hierarchical planning, perforation planning and/or volume increase planning.Afterwards, if necessary, can adjust many well planning.For example, if the indication of the fracture stimulation in well volume increase result will be overlapping with the well of the vicinity in the perforation district with planning, can eliminate or redesign so the perforation district of this planning in the well of the well of this vicinity and/or this vicinity.In contrast, if because the oil-producing area is just too far away so that can not effectively increase production this oil-producing area for the first crack well, perhaps because the existence of dry or heavily stressed barrier so that the first crack well can not effectively increase production this oil-producing area, and cause the specific region that the crack treatment simulated can not earth penetrating, can comprise so the second well/branch or new perforation district, so that the path to untreated zone to be provided.The 3D reservoir model can be considered simulation model, and the position candidate of the second well/branch or increase adjunction morphism porose area is bored in indication.Process for the ease of the oil field operation person, space X can be provided '-Y '-Z ' position.

Stimulation work after the planning

Embodiment can also comprise real-time processing optimization (or after the task workflow) 451, is used for analyzing stimulation work, and upgrades volume increase planning during actual stimulation work.Can during volume increase planning (for example carry out pressure break, injection or reservoir is carried out the volume increase of alternate manner in the well site) is implemented in the well site, carry out to process in real time and optimize 451.Processing optimization can relate to volume increase planning and the real-time oilfield stimulation 455 of calibration testing 449, implementation 448 generation in volume increase planning 447 in real time.

Can carry out alternatively calibration testing 449 by result's (being the simulation fracture model) and the observation data of relatively volume increase planning 447.Some embodiment can carry out calibration after volume increase planning with calibration comprehensively in the volume increase planning process, and/or increase production or the real-time implementation of any other processing procedure in apply calibration.In U.S. Patent application No.2011/0257944, described the example of the calibration of fracture or other stimulation work, by reference its full content has been herein incorporated.

Based on the volume increase planning that in volume increase planning 447 (and calibrate 449, if carried out calibration), generates, can carry out 448 oilfield stimulation 445.Oilfield stimulation 455 can relate to real-time measurement 461, real-time interpretation 463, in real time volume increase design 465, exploit 467 and control in real time 469 in real time.Measuring in real time 461 can carry out such as the sensor S as shown in Fig. 3 .1 in the well site example.Can generate observation data with real-time measurement result 461.Can use the observed result from the stimulation treatment well, such as shaft bottom and ground pressure, come calibrating patterns (traditional pressure coupling workflow).In addition, also can comprise On Microseismic Monitoring Technique.Such space/time observation data and prediction fractured model can be compared.

Based on collected data, can be at the scene in or carry out real-time interpretation 463 outward.The execution of in real time volume increase design 465 and production forecast 467 can be similar to volume increase design 468 and production forecast 470, but is based on the additional information that generates during the actual oilfield stimulation 455 of carrying out in the well site.Can provide and optimize 471, so that along with the oilfield stimulation progress, iteration be carried out in real-time volume increase design 465 and production forecast 467.In real time volume increase 455 for example can relate in real time pressure break.Described the example of real-time pressure break among the U.S. Patent application No.2010/0307755, by reference its full content has been herein incorporated.

Real-time control 469 can be provided, so that along with the collection of information, and obtain understanding to operating condition, adjust the stimulation work at place, well site.In real time control 469 provides feedback loop, to carry out 448 oilfield stimulation 455.Can for example carry out real-time control 469 with surface units 334 and/or downhole tool 306.1-306.4, with change operating condition, such as perforation position, injection pressure etc.Although described the feature of oilfield stimulation 455 with real time job, can be in real time or carry out on demand to process in real time and optimize one or more features of 451.

Optimize that the information that generates during 451 can be used for upgrading this process and to the feedback of reservoir characterization 445 in real time processing.Design/model modification 453 comprises processes rear assessment 475 and Renewal model 477.Assess after processing to relate to analyzing to process in real time and optimize 451 result and adjust in case of necessity input and the planning of using in other well site or the wellbore applications.

Assessment 475 can be as input with Renewal model 477 after processing.The data of collecting from subsequently drilling well and/or exploitation alternatively, can feed back to reservoir characterization 445 (for example 3D earth model) and/or volume increase planning 447 (for example the well planning module 465).Can lastest imformation, with remove error in initial modeling and the simulation, with proofread and correct in the initial modeling deficiency and/or to confirm (substantiate) this simulation.For example, spacing and the orientation that can adjust well illustrate data newly developed.In case upgrade 477 model, this process just can undesirably repeat.Can carry out one or more well sites, well, stimulation work or variant with the method 400.

In given example, can be by making up the 3D model of subterranean strata, and carry out semi-automatic method and carry out stimulation work, method that wherein should semi-automation relates to subterranean strata is divided into a plurality of discrete intervals, attribute based on interval place subterranean strata characterizes each interval, interval is grouped into one or more drilling well sites, and drilling well in each drilling well site.

Tight gas layer of sand (sand) is used

The below provides example volume increase design and the downstream workflow of the unconventional reservoir (referring to the reservoir 304.1-304.3 of for example Fig. 3 .1) that can be used for relating to the tight gas sandstone.For tight gas sandstone reservoir workflow, can use conventional volume increase (being fracturing) method for designing, such as single or multiple lift plane fractured model.

Fig. 5 A and 5B illustrate the example of the classification that relates to tight gas layer of sand reservoir.Multistage completion consultant can be provided, to carry out reservoir planning for the tight gas sandstone reservoir, wherein on the major part on the stratum of contiguous well (for example 336.1), can disperse or scatter a plurality of thin layers (for example reservoir 304.1-304.3 among Fig. 3 .1) that are rich in the district of hydrocarbon.Can use a model to develop nearly wellbore region model, wherein can catch the key characteristic such as reservoir (produce oil) district and geomechanics (stress) district.

Fig. 5 A shows the log 500 of the part of well (for example well 336.1 of Fig. 3 .1).This log can be the chart such as the measurement result of resistivity, permeability, porosity or other reservoir parameter that obtains along well bore logging.In some cases, as shown in Figure 6, a plurality of logs 600.1,600.2 and 600.3 can be combined as merged curve 601, to be used for method 501.Merged curve 601 can be based on the weighted linear combination of a plurality of logs, and can the input cut-off of correspondence correspondingly be weighted.

Log 500 (or 601) can be associated with method 501, and method 501 relates to based on the data that provide analyzes log 500 to limit with interval (569) border 568 along log 500.Border 568 can be used for along well identification (571) oil-producing area 570.Can specify along well (573) Crack Element 572.Can carry out (575) grading design, with along well restricted class 574.Finally, can design (577) perforation 576 along the position in the level 574.

Can input based on these, come the identifying processing interval to the division of the discrete interval (multistage) of many groups with semi-automatic method, and calculate the configuration that perforation is arranged.Reservoir (petrology) information and completion (geomechanics) information can be introduced model as factor simultaneously.Can determine the border, district based on the input log.Can limit the district by the applied stress log.Can select any combination that other is inputted log or represents the log of reservoir formation.

Can introduce the reservoir oil-producing area from outside (for example petrology explanation) workflow.This workflow can provide the oil-producing area recognition methods based on a plurality of log cut-offs.Under latter event, each input log value (being default log) can comprise water saturation (SW), porosity (Phi), intrinsic permeability (Kint) and clay volume (Vcl), but also can use other suitable log.The log value can be distinguished by their cutoff.If satisfy all cut-off conditions, can be the oil-producing area with the sounding mark of correspondence then.Can use minimum thickness, KH (permeability multiply by district's thickness) and PPGR (pore pressure grad) cut-off condition of oil-producing area and finally eliminate barren oil-producing area.These oil-producing areas can be inserted the section model based on stress.Can check the minimum thickness condition, to avoid producing small district.Can also select the oil-producing area, and wherein merge the border based on stress.In another embodiment, the 3D section model that provides by the reservoir modeling process can be used, and basic border and output area, meticulous district can be inserted.

For each oil-producing area of identifying, can carry out based on the simple fracture height growth of net pressure or shaft bottom processing pressure and estimate to calculate, and Crack Element (FracUnit) is made up to form in overlapping oil-producing area.Can limit the volume increase level based on one or more following conditions: the minimum range between minimum clear height, maximum total height and the level.

Can scan the FracUnit group, and check may making up of continuous FracUnit.Can optionally eliminate the particular combinations of violating specified conditions.Effective combination of identifying can be used as the classification scene.Maximum total height (=level length) can change, and repeats combination inspection for every kind of variation.Can count according to the classification scene to frequent appearance in the set of all outputs, to determine final result.In some cases, do not satisfy all conditions because there is single grading design to be determined, so can not find ' output '.In this case, the user can be in initial conditions assigned priority.For example, maximum total height can satisfy, and can ignore the minimum range between the level, to find best solution.

If the STRESS VARIATION in the level is remarkable, then can limit based on the quality of oil-producing area perforation position, exit point density and exit point quantity.If STRESS VARIATION is large, can carry out the current limliting method so, to determine the distribution of exit point between Crack Element.If necessary, user's choice for use current limliting method (for example step by step) alternatively.In each FracUnit, can determine the perforation position by selected KH (permeability multiply by perforation length).

Can use multistage completion consultant, shale gas reservoir (gas shale reservoir) is carried out reservoir planning.Well in the great majority exploitation is essentially horizontally to get out in the situation of (perhaps depart from from vertical well and get out), and the whole lateral part of well can be arranged in target reservoir stratum (referring to the reservoir 304.4 of for example Fig. 1).Under these circumstances, can assess respectively reservoir attribute and completion mutability of attribute.Process interval and can be divided into one group of interval that adjoins (multistage).Can divide, so that reservoir attribute and completion attribute are similar in each level, provide the maximum covering to the reservoir contact to guarantee result's (well completion design).

In given example, can utilize the method for partial automation to carry out stimulation work with the multi-stage perforator design of identifying best in the well.Can based on key characteristic, such as reservoir oil-producing area and geomechanics stressed zone, develop nearly wellbore region model.Can be divided into the discrete interval of many groups with processing interval, and can calculate the configuration that perforation is arranged in the well.Can utilize the volume increase design work flow process that comprises single or multiple lift plane fractured model.

Shale is used

Fig. 7-12 illustrates the classification to the unconventional application that relates to shale gas reservoir (for example reservoir 304.4 among Fig. 3 .1).Figure 13 illustrates for the corresponding method 1300 of the volume increase of shale reservoir being carried out classification.For the shale gas reservoir, can utilize the description to the reservoir of dry.Dry can be modeled as one group of plane geometry object, is called " discrete fractures network " (referring to for example Fig. 3 .2-3.4).Input dry data can make up with the 3D reservoir model, with the heterogeneity (completely contradicting with the plane fractured model) of explanation (account for) shale reservoir and network fractured model.Can use this information and predict the hydraulic fracture progress.

Fig. 7 to 12 illustrates the completion consultant for the horizontal well on the stratum that penetrates the shale reservoir.Completion consultant can generate multistage volume increase design, comprises one group of (contiguous) classification interval that adjoins and one group of (consecutive) classification that links up.Can also comprise the additional input such as default district or any other interval information in the volume increase design, to avoid arranging level.

Fig. 7-9 illustrates the generation of the composite quality index of shale reservoir.Can assess along reservoir quality and the completion quality of the traversing section of well.The reservoir quality index can comprise for example various requirement or standard, and more than or equal to about 3%, gas oil in place (GIP) is greater than about 100scf/ft such as total organic carbon (TOC) ³, kerabitumen is greater than height, and the shale porosity is greater than about 4%, and gas relative permeability (Kgas) is greater than about 100nD.The completion quality index can comprise for example various requirement or standard, is ' low ' such as stress, and resistivity is greater than about 15 ohm meters, and clay is less than 40%, and young's modulus of elasticity (YM) is greater than about 2 * 10 ⁶Psi (), poisson's ratio (PR) is less than about .2, and neutron porosities is less than about 35%, and the density porosity is greater than about 8%.

Fig. 7 schematically illustrates the combination of log 700.1 and 700.2.Can generate reservoir quality index 701 by merged curve 700.1 and 700.2.Log can be the reservoir log, such as permeability, resistivity, the porosity log from well.Log be adjusted to square for assessment of.Can be based on to log 700.1 and 700.2 relatively quality index is separated (1344) being the zone, and be categorized as (G) and poor (B) interval according to the binary system log.For the well in considering, can be with any zone label of satisfying all reservoir quality conditions for well, and be poor with other zone label.

Can use applicable log (such as young's modulus of elasticity, poisson's ratio etc. is used for the completion log), form in a similar fashion other quality index, all in this way completion quality index.The quality index that can make up (1346) such as reservoir quality 802 and completion quality 801 forms composite quality index 803, as shown in Figure 8.

The level that Fig. 9-11 illustrates the shale reservoir limits.With composite quality index 901 (can be the composite quality index 803 of Fig. 8) and by poor stress log 903 combinations (1348) that are segmented into stress block of stress gradient.The result is the Zu Heyingli ﹠amp that is divided into spaced GB, GG, BB and BG classification; Composite quality index 904.Can be by applied stress lateral curve 903 along quality index 904 restricted classes, to determine the border.Determine one group of preliminary level border 907 in the poor position greater than a certain value (for example, default value can be 0.15psi/ft) of stress gradient.This process can produce one group of uniform stress block along combined stress and quality index.

Stress block can be adjusted into the piece of desired size.For example, in the place of interval less than minimum level length, can by its piece with vicinity is merged to form refinement composite quality index 902, eliminate little stress block.Can use and have a poor piece of less stress gradient in two adjacent pieces as merging target.In another example, in the situation that interval greater than maximum level length, can disassemble large stress block, to form another refinement composite quality index 905.

As shown in figure 10, in the place of interval greater than maximum level length, bulk 1010 can be decomposed (1354) is a plurality of 1012, to form level A and B.After decomposing, can form refinement composite quality index 1017, then with level A and B refinement composite quality index 1017 is decomposed into non-BB composite quality index 1019.Under certain situation shown in Figure 10, can avoid large ' BB ' piece and non-' BB ' piece such as ' GG ' piece are grouped in the identical level.

If as in the quality index 1021, ' BB ' piece is enough large, so quality index can conversion (1356) to its oneself level, as shown in the quality index 1023 after the conversion.Can check additional constraint, such as hole deviation, nature and/or induce the existence in crack, come so that level characteristics is even.

As shown in figure 11, the process that can use among Figure 10 generates quality index 1017, and is decomposed into the piece 1012 that is shown grade A and B.Can in quality index 1117, identify the BB piece, and be broken down into the conversion quality index 1119 with three level A, B and C.As shown in FIG. 10 and 11, can undesirably generate the level of various quantity.

As shown in figure 12, can settle (1358) perforation bunch (or perforation) 1231 based on classify result and composite quality index 1233 of level.In the shale well completion design, (equidistant, for example per 75 feet (22.86m)) arranges perforation equably.Can avoid approaching the perforation (for example 50 feet (15.24m)) on level border.Can check the composite quality index in each perforation position.Indicated such as horizontal arrow, the perforation in ' BB ' piece can be moved to contiguous immediate ' GG ', ' GB ' or ' BG ' piece.If perforation drops in ' BG ' piece, then further fine granularity GG, GB can be carried out, BG, BB reclassify, and perforation is arranged in the interval that does not comprise BB.

Can carry out balancing of stresses, be similar (for example within 0.05psi/ft) with stress gradient value where in the level of location.For example, if user input is 3 perforations of each level, can searches for so and satisfy condition the best (that is, minimum stress gradient) position of (for example, the spacing between the perforation and within the scope of stress gradient).If the location is not then searched for and can be continued and repetition next optimum position, until it finds for example three positions that are used for placing three perforations.

If the stratum is inhomogeneous, perhaps by large dry and/or heavily stressed barrier crosscut, then may need the well planning that adds.In one embodiment, subsurface formations can be divided into the discrete volumes of many groups, can be based on characterizing each volume such as geophysics's attribute on stratum and with the information of the vicinity of dry.For each factor, can be to the index of volume appointment such as " G " (good), " B " (poor) or " N " (medium).Then can be with a plurality of combined factors together, to form composite index, such as " GG ", " GB ", " GN " etc.The unlikely position that penetrates by fracture stimulation of volume indication with a plurality of " B ".Volume with one or more " G " can be indicated more likely the position that can process by fracture stimulation.A plurality of volumes can be grouped into one or more drilling well sites, wherein each well site represents be used to the potential site that holds well or branch.Can optimize spacing and the orientation of a plurality of wells, so that the complete stratum that is fully increased production to be provided.Can undesirably repeat this process.

Although the particular technology that Fig. 5 A-6 and Fig. 7-12 all illustrates for classification, the alternatively various piece of combined classification.Depend on the well site, can use the version of grading design.

Figure 14 is the flow chart that the method (1400) of stimulation work is carried out in diagram.The method relates to: the petrology, geology and the geophysical data that obtain (1460) relevant well site; Based on comprehensive petrology, geology and geophysical data, carry out (1462) reservoir characterization with the reservoir characterization model, generate mechanics (mechanical) earth model (referring to for example, increasing production in advance planning 445).The method also relates to: generate (1466) volume increase planning based on the mechanics earth model that generates.Generating (1466) can relate to, and for example, the volume increase of Fig. 4 is planned well planning 465, grading design 466, volume increase design 468, the production forecast 470 in 447 and optimized 472.Then, by in continuous feedback loop, carrying out repetition (1462), optimize (1464) volume increase planning, until generate the volume increase planning of optimizing.

The method can also relate to the calibration (for example 449 among Fig. 4) that execution (1468) is planned the volume increase of optimizing.The method can also relate to: carry out (1470) volume increase planning; Carrying out volume increase planning period measurement (1472) real time data; Carry out in real time volume increase design and production forecast (1474) based on real time data; By repeating in real time volume increase design and production forecast, the volume increase planning that comes real-time optimization (1475) to optimize is until produce the volume increase planning of real-time optimization; Plan to control (1476) stimulation work based on the volume increase of real-time optimization.The method can also relate to: assessment (1478) volume increase planning after finishing volume increase planning; And upgrade (1480) reservoir characterization model (referring to for example, design/model modification 453 of Fig. 4).Can carry out these steps with various orders, and undesirably carry out repetition.

Although the above only describes several exemplary embodiments in detail, those skilled in the art will easily understand, in exemplary embodiment many modifications may be arranged and not break away from fact the present invention.Correspondingly, all such modifications all are intended to be included in of the present disclosure as within the scope defined in the appended claims.In claims, the clause intention that device adds function covers the structure of the function that execution described herein sets forth, and not only comprises equivalent structures, and comprises equivalent structure.Therefore, in the border, field that wooden parts are secured together, although nail and screw may not be equivalent structures, because nail adopts periphery that wooden parts are fixed together, and screw adopts helical surface, but nail and screw can be equivalent structures.Except the restriction that claim clearly uses statement ' device is used for ' and the function that is associated to make together, the applicant represents that clearly not wishing to quote the 6th section of 35U.S.C § 112 comes any claim is here made any restriction.

In given example, can carry out stimulation work, relate to: for the processing interval in the well that penetrates subterranean strata, assess respectively reservoir attribute and completion mutability of attribute; Be divided into one group of interval that adjoins (in the processing interval that each is divided, reservoir attribute and completion attribute can be similar) with processing interval; By using one group of plane geometry object (discrete fractures network) to design the stimulation treatment scene, with exploitation 3D reservoir model; And with dry data and the combination of 3D reservoir model, with the heterogeneity on consideration stratum, and prediction hydraulic fracture progress.

Claims

1. method of the well site with the reservoir that is arranged in subterranean strata being carried out stimulation work comprises:

Based on comprehensive well site data, carry out reservoir characterization with the reservoir characterization model, to generate the mechanics earth model;

Based on described mechanics earth model, generate volume increase planning by carrying out well planning, grading design, volume increase design and production forecast; And

Optimize described volume increase planning by in feedback loop, repeating described volume increase design and described production forecast, until generate the volume increase planning of optimizing.

2. method according to claim 1, wherein said comprehensive well site data comprise the comprehensive combination of petrology, geomechanics, geology and geophysical data.

3. method according to claim 2 also comprises: combination at least part of who measures petrology, geomechanics, geology and the geophysical data at place, described well site.

4. method according to claim 1 is wherein optimized described volume increase planning and is comprised: repeats described well planning, grading design, volume increase design and production forecast in feedback loop, until generate the volume increase planning of described optimization.

5. method according to claim 1 also comprises: carry out the volume increase planning of described optimization at place, described well site.

6. method according to claim 5 also comprises: measure real time data in volume increase planning period of carrying out described optimization from described well site.

7. method according to claim 6 also comprises: carry out real-time interpretation based on measured real time data.

8. method according to claim 7 also comprises: carry out real-time volume increase design and production forecast based on described real-time interpretation.

9. method according to claim 8 also comprises: come the volume increase planning of the described optimization of real-time optimization by repeat described real-time volume increase design and described production forecast in feedback loop, until generate the volume increase planning of real-time optimization.

10. method according to claim 9 also comprises: plan to control described stimulation work based on the volume increase of described real-time optimization.

11. method according to claim 10 also comprises: after the volume increase planning of carrying out described optimization, assess described well site.

12. method according to claim 11 also comprises: upgrade described reservoir characterization model based on described assessment.

13. method according to claim 12 also comprises: use the reservoir characterization model that upgrades to repeat the described execution of described reservoir characterization, described generation and described optimization.

14. method according to claim 1 also comprises: calibration well volume increase planning.

15. method according to claim 14 also comprises: carry out the well volume increase planning of the optimization of calibrating.

16. method according to claim 1 also comprises: based on the assessment to the real time data that gathers in volume increase planning period of carrying out described optimization, upgrade described reservoir characterization model.

17. method according to claim 1, wherein said grading design is carried out by following step: limited boundary on the log of described well; Identify the oil-producing area based on described border along described well; In described oil-producing area, specify Crack Element; Based on described Crack Element design level; And design the perforation position based on designed level.

18. method according to claim 1, wherein said grading design is carried out by following step: generate a plurality of quality index according to a plurality of logs; Make up described a plurality of quality index to form the composite quality index; Described composite quality index and stress log are made up, to form combined stress and composite quality index; Identify the classification of the piece of described combined stress and composite quality index; Based on described classification, along described combined stress and composite quality index restricted class; And based on described classification, in described level, optionally settle perforation.

19. method according to claim 1 is wherein carried out described volume increase design with fractured model.

20. method according to claim 1 is wherein carried out described production forecast with the finance input.

21. method according to claim 1, wherein said reservoir comprise one at least one tight gas layer of sand reservoir and the shale reservoir.

22. a system that is used for the well site with the reservoir that is positioned at subterranean strata is carried out stimulation work, described system comprises:

The volume increase instrument, described volume increase instrument comprises:

The reservoir characterization unit, it carries out reservoir characterization based on the well site data that comprise comprehensive well site data with the reservoir characterization model, to generate the mechanics earth model;

The volume increase planning unit, it generates volume increase planning based on described mechanics earth model by carrying out well planning, grading design, volume increase design and production forecast; And

Optimizer, it optimizes described volume increase planning by repeat described volume increase design and production forecast in feedback loop, until generate the volume increase planning of optimizing.

23. system according to claim 22 also comprises: at least one can be placed in the downhole tool in the well of locating in described well site, and described at least one downhole tool can be operably connected to described volume increase instrument.

24. system according to claim 23, wherein said at least one downhole tool comprise wireline logging instrument, drilling tool, perforation tool, implantation tool and combination thereof one of at least.

25. system according to claim 23, wherein said at least one downhole tool comprises at least one sensor, is used for measuring the well site parameter.

26. system according to claim 22 also comprises: real-time unit, it comes the volume increase planning of the described optimization of real-time optimization by repeating in real time described volume increase design and production forecast, until generate the volume increase planning of real-time optimization.

27. system according to claim 26 also comprises: renovator, its volume increase based on described real-time optimization plans to upgrade described reservoir characterization model.

28. system according to claim 22, wherein said volume increase instrument can be placed in one of surface units, downhole tool and combination thereof.

29. system according to claim 22 also comprises: calibrator, for the volume increase planning of calibrating described optimization.

30. system according to claim 22, wherein said volume increase planning unit comprises grading design instrument, volume increase design tool, production forecast instrument and well Planning Tool.

31. system according to claim 22 also comprises: surface units can be operably connected to described optimizer.

32. a method of the well site with the reservoir that is arranged in subterranean strata being carried out stimulation work comprises:

Based on described mechanics earth model, generate volume increase planning by carrying out well planning, grading design, volume increase design and production forecast;

Optimize described volume increase planning by in feedback loop, repeating described volume increase design and described production forecast, until generate the volume increase planning of optimizing;

Carry out in real time the volume increase planning of described optimization;

Come the volume increase planning of the described optimization of real-time optimization by in feedback loop, repeating in real time described volume increase design and described production forecast, until generate the volume increase planning of real-time optimization; And

Plan to upgrade described reservoir characterization model based on the volume increase of described real-time optimization.